JP2003263300A - Program, apparatus, and method for predicting expendable supplies demand - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To establish a demand predicting method for consumables, related to bodies of products and carry out planning support for consumables business, based on results of the demand forecast method. <P>SOLUTION: A consumables demand predicting program forecasts the consumption amount of expendable supplies for outputting future output articles through the output amount of the output articles output from the products and sold amount of the expendable supplies. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a consumables demand forecasting apparatus, method, and program, and in particular, before and after a product with consumables (hereinafter referred to as "main body") is sold in the market, its main body is consumed. The present invention relates to a consumables demand forecasting program, a device, and a method for forecasting the demand for consumables.

[0002]

2. Description of the Related Art Conventionally, a product (hereinafter, referred to as a "main body") that has a consumable item such as a copying machine or a printer is
The demand for the consumables consumed by the main body was empirically determined based on the past sales record of the consumables, the market trend, and the sales plan quantity of the main body.

As described above, since the demand forecast (hereinafter referred to as "demand forecast") depends on the rule of thumb and know-how, the forecast value of the demand varies depending on the skill and experience of the individual who makes the forecast. , The accuracy of the predicted value was impaired. As described above, the demand forecasting method for consumables of a certain product has not been realized due to the large number of parameters, the complexity of calculation, and the difficulty of a systematic approach to problem solving.

[0004]

SUMMARY OF THE INVENTION The present invention establishes a demand forecasting method for consumables related to the main body, which could not be realized in the past, and based on the results, support planning of consumables business (new product introduction). The purpose is to make plans and replacement plans.

In order to realize these, there are the following technical problems. A method of predicting the number of operating main units that use consumables. A method of predicting an average print volume (hereinafter referred to as "PV") of a main body of a consumable item used. A method for predicting the total PV of a main body of a consumable item used. A method of predicting the quantity of consumables used in the past and the quantity of consumables to be used in the future from the total forecast PV of the main body in which it is used. A method of predicting the number of operating main units when there are not enough sales records (planning stage, or just after start-up). A method of predicting the average PV of the main body when there is not enough sales record. A method for determining the number of durable consumables when there are not enough sales records. A correction method that corrects (increases or decreases) the forecast results in consideration of market trends. A method of correcting seasonal fluctuations for forecast results.

[0006]

In order to solve the above problems, the consumable goods demand forecasting program of the present invention forecasts the demand of consumable goods consumed when an output device for outputting an output product outputs the output device. Is a consumables demand forecasting program having a command to a computer for inputting an output amount input control function for controlling an output amount input means for inputting an output amount of an output product output from the product, and an input of a sales amount of consumables. A sales volume input control function for controlling the sales volume input means, a storage control function for controlling storage of the output volume and the sales volume in a memory, and a future output product from the output volume and the sales volume Prediction function to predict the consumption of consumables for
Is realized by a computer.

Further, the consumable goods demand forecasting program of the present invention is a consumable goods demand forecasting program having a command to a computer for predicting the demand of the consumable goods consumed when the output device for outputting the output makes the output. And an output amount input control function for controlling an output amount input means for inputting an output amount of an output product output by the product per unit time, and a sales amount input for inputting a sales amount of consumables per unit time A sales volume input function for controlling the means, a storage control function for controlling the output volume and the storage of the sales volume in a memory, and a consumable product for outputting a future output product from the output volume and the sales volume And a storage function of storing the consumption amount of the consumable goods predicted by the prediction function in a memory.

The consumable goods demand forecasting method of the present invention is a consumable goods demand forecasting method for forecasting the demand of consumable goods consumed when an output device for outputting an output product outputs the product. An input step of inputting an output amount of an output product to be output and a sales amount of the consumable item, a storage step of storing the output amount and the sales amount in a memory, and a future output product based on the output amount and the sales amount. And a prediction step of predicting the consumption amount of the consumable product for outputting.

The consumable goods demand forecasting apparatus of the present invention is a consumable goods demand forecasting apparatus having a command for predicting a demand for a consumable article consumed by an output device for outputting an output. An output amount input means for inputting an output amount of an output product output from the product, a sales amount input means for inputting a sales amount of a consumable item, a storage means for storing the output amount and the sales amount, And a predicting means for predicting a consumption amount of a consumable product for outputting a future output product from the output amount and the sales amount.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION An object of the present invention is to establish a demand forecasting method for a consumable item for a main body, which could not be realized conventionally, and to support the planning of a consumable item business based on the result. .

In the present embodiment, the main body is a copier / printer and the consumables are paper, toner, and drums used in the copier / printer. For example, the main body is a car and the consumables are It may be gasoline (fuel) used in a car.

The present embodiment has the following configuration. [1. System configuration] [2. Prediction of Average PV (Print Volume) of Main Body (Average PV Prediction Block)] [3. Prediction of Total PV of Main Body (Total Predicted PV Block)] [4. Consumables demand forecast (consumables forecast block)] [5. Display of prediction result] [6. Switching of prediction method] [7. Consumables Macro Demand Forecast] Hereinafter, a preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

[1. System Configuration] FIG. 1 is a diagram showing a configuration of an information processing apparatus for realizing the present invention.

Reference numeral 101 denotes a CPU, which controls each part in the information processing apparatus and also controls for realizing the processing shown in the present embodiment.

An input unit 102 allows an operator of the information processing apparatus to input information. The input unit 102 includes, for example, a keyboard, a mouse, a digitizer, and the like.

An output unit 103 displays information to the operator of the information processing apparatus. The output unit 103 has, for example, C
There are RTs and liquid crystal displays. The output unit 103 displays information that prompts the operator to input various kinds of information, and displays a prediction result described later in a graph and / or a table.

An external storage device 104 reads and writes information on a medium separate from the information processing device. The external storage device 104 includes, for example, an FD drive, an MO drive, a CD-R drive, and the like.

Reference numeral 105 denotes a ROM (Read Only M
memory), which is a read-only memory. ROM
A PROM (Programmable Ro) 105 allows a user to electrically write a program.
m) and a mask ROM in which the contents are written at the time of manufacturing, but any ROM may be used in the present embodiment.

Reference numeral 106 denotes a RAM (Random Acce).
ss Memory), which is a memory that allows free writing and free reading. The RAM 106 has a function of temporarily storing data when performing the processing of this embodiment.

Reference numeral 107 denotes a network interface, which enables connection to networks such as the Internet and LAN / WAN. The network interface 107 includes, for example, a modem and a network card. Further, the communication is realized by a network protocol such as TCP / IP.

Reference numeral 108 denotes an internal storage device, which is a device for storing information in the information processing device. A hard disk is an example of the internal storage device.

Reference numeral 109 denotes a bus, which exchanges various data between respective blocks in the information processing apparatus and supplies electric power. The bus 109 includes address lines, data lines,
Consists of control lines, power / ground lines, etc.

The operation of each unit in the information processing apparatus will be described below.

First, the CPU 101 is a program (hereinafter referred to as "program") for realizing the processing (function) stored in the ROM 105, the internal storage device 108, or the external storage device 104 and shown in the present embodiment. ) Is read into the RAM 106. Then, the program read into the RAM 106 is expanded on the RAM 106. The program may be interpreted or compiled.

The program expanded on the RAM 106 realizes various processes in cooperation with the CPU 101.

FIG. 17 shows the module structure of the program.

The program is an "input control module"
The modules are roughly divided into “calculation modules”, “output modules”, “network modules”, etc., and each module is further divided into modules.

The processing of the present invention by this program is
It is specifically realized by using hardware resources such as the CPU 101 and the RAM 106. That is, when the program is read into the information processing device, the specific information processing device or its operating method according to the object of the present invention is constructed by the specific means in which the software and the hardware resources cooperate. Become.

Further, the number of programs need not be one, and may be a combination of a plurality of programs. For example, the processing of the present invention may be realized by a program (for example, a macro program) that uses a part of the functions of general-purpose spreadsheet software.

The CPU 101, in cooperation with the input control module in the program, prompts the user for input through the output unit 103, realizes input of data from the user through the input unit 102, and receives the input data. External storage device 1
04, RAM 106, internal storage device 108 and the like.

Further, the CPU 101 cooperates with a calculation module in the program to execute various calculations necessary for the processing of the present invention (for example, calculations for predicting the consumption amount of consumables).

Further, the CPU 101 cooperates with the output module in the program to display various information (for example, input request, calculation result, etc.) to the user via the output unit 103.

Further, the CPU 101 cooperates with a network module in the program to realize connection with a network (not shown) such as LAN or WAN, and exchange various data with external devices via the network. make it happen.

It goes without saying that the structure of the program is not limited to the above program modules.

In predicting the sales quantity (demand amount) of the consumables of the main body in the present invention, the prediction of the operating number of the main bodies using the consumables (main body operating number prediction block) and the average PV (average) The total forecast PV is calculated based on the (PV forecast block) (total forecast PV block), and the demand forecast of the consumable item (consumable item forecast block) is performed with this.

FIG. 12 is a diagram showing a main body operating number prediction block, an average PV prediction block, and a total prediction PV block.

FIG. 13 is a diagram showing a consumables prediction block.

Each prediction block will be described below.

[1. Prediction of Operating Number of Main Units (Block for Predicting Operating Number of Main Units)] FIG. 8 is a diagram showing a processing flow when predicting the operating number of main units.

The constants, variables, and functions used in this processing are as follows. t: A unit time (for example, month) at which the data is observed, where the main body sales start date is 0 (starting point). a (t): Main unit sales record number in t month b (t): Main unit sales plan number in t month x (t): Main unit sales record number in t month d: Delay coefficient (for example, months) y (t) : Actual operation number of main unit in t month T: Last month when actual operation number of main unit was observed (y (t)
(Observed period, number of valid cases)

[Outer 1]

S (j): Survival rate function (remaining probability after the installation of the main body j months) f (t): Death probability density function of the main body (death probability in unit time after the installation of the main body j months) J (t ): Installation diffusion coefficient μ: Average life of the main body σ: Standard deviation of average life of the main body φ: Coefficient of variation of average life of the main body h: Reliability coefficient of prediction of number of operating main bodies s: Standard error of predicted number of operating main bodies Ag: Aging coefficient Ed: The prediction of the number of operating main bodies will be described below.

The prediction of the number of operating main bodies is executed for each prediction processing unit. The prediction processing unit is a unit divided into products and regions. The prediction processing unit is input in advance by the user via the input unit 102 (needless to say, the subject that urges the user to input or transfers the input data to each unit in the information processing apparatus is the CPU 101),
It is stored in the RAM 106. Further, as the prediction processing unit, one that is stored in advance in the external storage device 104 or the internal storage device 108 may be used.

FIG. 2 is a diagram showing a table for explaining prediction processing units in this embodiment.

In FIG. 2, there are four products, a copy machine A, a copy machine B, a printer A and a printer B, and the regions are five countries of Japan, the United States, the United Kingdom, Germany and France. In this embodiment, the region is a country unit, but it may be a local government unit or a sales company responsible region unit. Hereinafter, this product is referred to as a "product model", and the unit of this area is referred to as a "base".

In FIG. 2, the prediction processing unit indicated by "○" indicates that the product is sold at the site. That is, all the products are sold in Japan, but only the copy machine A and the printer B are sold in the UK.

The procedure for predicting the number of operating main bodies for each prediction processing unit will be described below.

[Step m0] Main Unit Sales Actual Planned Unit Number Calculation Step (S802) In this step, the main unit sales actual unit number a (t) or the main unit sales actual unit number b (t) is used to determine the main unit sales actual unit number x.
Generate (t).

First, the data of the actual sales quantity a (t) of the main body and the planned sales quantity b (t) of the main body are input. Here, "input" means A. Data input by the user via the input unit 102. B. Input of data stored in the external storage device 104 or the internal storage device 108 C. The network interface 107 is used to input data received from an external device via the network. This "input" function is CP based on the program.
It is realized by U101 and the like. The input may be performed based on a user's instruction, or may be realized according to a certain rule (eg, periodically) based on a program.
Hereinafter, unless otherwise specified, “input” means the above A.
B. C. Input.

The main body sales record number a (t) and the main body sales plan number b (t) that have been input are stored in the RAM 106. Then, the following arithmetic processing is performed by the CPU 101 based on the arithmetic module in the program. (Equation 1) a (t) = null then x (t) = b (t) a (t) ≠ null then x (t) = a (t) The main unit sales record a (t) is By referring to the data actually sold by a dealer or the like, it is possible to obtain an almost accurate transition of the sales volume for each prediction processing unit. The main unit sales plan b (t) is a transition of the planned value of the sales volume determined from the sales target, the economic situation, and the like.

FIG. 3 shows from January 2001 to January 2001.
It is a figure which shows an example which calculates the main body sales result planned quantity x (t) from the main body sales actual quantity a (t) and main body sales planned quantity b (t) by February.

From February to August 2001, the main unit sales record number a (t) has a value, so the main unit sales record number x (t) becomes a (t). On the other hand, 2001
Since September, 2014, the main unit sales record a (t) has no value (null), so the main unit sales record plan x
(T) is the main unit planned number b (t).

As described above, it is not necessary to make a subsequent prediction by using the main unit sales record number x (t) which is a combination of the main unit sales record number a (t) and the main unit sales plan number b (t). Is one of the features.

This step will be described in more detail. In this step, the actual data is given priority over the planned data.

It is conceivable that the actual sales volume a (t) and the planned sales volume b (t) are separated based on time. For example, "the main unit sales performance plan number x (t) is 2
Before September 001, the number of units sold was a (t),
After October 2001, the number of units sold is b (t). Is possible. However, inconvenience arises in the processing based on the time due to the time lag etc. required for the acquisition of data. In particular, when dealing with overseas data, the deviation of the data acquisition timing is significant.

Therefore, in the present invention, the above problems can be solved by discriminating (separating) according to "Yes" or "None" of the actual sales number a (t) of the main body as shown in the equation 1. .

[Step m1] Target base / target model selection step (S803) The above-mentioned prediction processing unit (base / main body model) is selected. In the present embodiment, for the sake of simplicity, one prediction processing unit is focused on for prediction processing, but a plurality of prediction processing units may be selected (after a plurality of prediction processing units are collectively predicted). The method of dividing the prediction result and calculating the prediction result for each prediction processing unit will be described later).

The "selection" of the prediction processing unit is similar to the above-mentioned "input", based on the command of the program, the CPU 10
1 and the like, the A. B. C. It is realized by either method of.

[Step m2] Main Unit Sales Actual Planned Unit x
(T) -Main unit operation record number y (t) Read step (S
804) The main unit sales record planned number x (t) and the main unit operation record number y (t) stored in time series are read into the RAM 106 for each prediction processing unit (one main unit model / one base). The actual number of operating main bodies y (t) is the operating status of the main units (the number of operating units) confirmed when the service engineer visits the customer for maintenance. This actual operating number y
The input of (t) is performed by the CPU 101 or the like based on a program, similar to the above-mentioned “input”. B. C. It is realized by either method of. These read data are used when calculating the main body operation predicted number which will be described later.

[Step m3] Main Unit Sales Start Date Detection Step (S805) The main unit sales start date is detected.

The CPU 101 searches the main unit sales record planned number x (t) stored in the RAM 106 from the beginning (searching from the left in FIG. 3), and when the first non-zero value is detected, the address start point ( R as t = 0)
It is stored in the AM 106. Taking FIG. 3 as an example, February 2001 is the starting point of the address.

FIG. 4 shows from January 2001 to 2001
It is a figure which shows an example of the main body operation | movement record number y (t) by February.

The CPU 101 searches the actual operation number y (t) of the main body stored in the RAM 106 from the end (searches from the right in FIG. 4), and then 0 or n for the first time.
When a value that is not null is detected, the start point of the address (t =
0) The effective number T counted from 0) is set, and the RAM 106
Remember.

From FIG. 4, the first non-zero value is detected in the actual operating number y (t) of the main body in 2001.
Since it is a month, the effective number T is 6 when the starting point of the address is February 2001.

[Step m3c] Prediction Mode Control Step (S806) One prediction method is selected from the two prediction methods. (Prediction method 1) Steps m3a1, m3a2, m3a
3, m3a4 is executed (prediction method 2) Steps m3b1 and m3b2 are executed.
Since the number of data such as (t) and the actual number of operation of the main body y (t) is required to some extent, it is not suitable when the data is small, and the prediction method of the prediction method 2 is often suitable. This prediction method may be set in advance (forced prediction mode), but the prediction method may be automatically selected (automatic prediction mode) as follows.

That is, the CPU 101 has the RAM 106.
If the number of valid cases T stored in is greater than or equal to a certain threshold N, the prediction method 1 is selected assuming that the prediction method 1 has sufficient data, while if the number of valid cases T is less than the threshold N, the prediction is performed. When it is judged that the method 1 does not have sufficient data, the prediction method 2 is selected (S807). This threshold value N is stored in the RAM 106 by the user in advance via the input unit 102 and the network interface 107.

For example, assuming N = 24, if the number of valid cases T is 24 or more, the prediction method 1 is selected, and if the number of valid cases T is less than 24, the prediction method 2 is selected.

Prediction method 2 is often selected when sufficient data cannot be obtained or during simulation at the sales planning stage.

In general, the prediction method 1 is the prediction method 2
It is said that the accuracy of the prediction is higher than that. In such a case, the prediction method 2 is forcibly selected as the forced prediction mode. However, in some cases, the prediction method 2 may be more accurate than the prediction method 1 even if there is sufficient data. In such a case, the forced prediction mode and the automatic prediction mode are properly used.

[Step m3a1] Correction Step Using Delay Coefficient (Prediction Method 1) (S809) There is a time difference (delay coefficient) from the actual sale of the main body to the installation (operation). That is, there is a delay coefficient d between the main unit sales record planned number x (t) and the main unit sales record y (t). If this time difference is taken into consideration, more accurate prediction becomes possible.

The method of calculating the delay coefficient d will be described below.

First, the installation diffusion coefficient J (t) is set.

FIG. 14 shows an example of the installed diffusion coefficient J (t) which is input to the RAM 106 in advance. The horizontal axis represents time and the vertical axis represents the installation diffusion coefficient J (t). In the present embodiment, the time on the horizontal axis is in months, but it goes without saying that it may be in years, weeks, or days.

The installation diffusion coefficient J (t) indicates the probability of the time when the main unit sales record planned number x (t) is installed in the future. Therefore, the CPU 101 causes the RAM
Monthly main unit sales performance plan number of units stored in 106 x
By multiplying (t) by the installation diffusion coefficient J (t), it is possible to know whether the main body sold (planned) that month is installed. The time integral of the installed diffusion coefficient J (t) is 1.

FIG. 15 is a diagram showing the number of installed units and the cumulative number of installed units for each month in this embodiment.

Description will be made taking July 2001 as an example. 20
The unit sales performance plan for the July 2001 x (t) is 53 units. These 53 units are not all installed in the market immediately after being sold, but will be installed gradually over time. This state is represented by the above-mentioned installation diffusion coefficient J (t).
Is. Since the installation diffusion coefficient J (t) in the first month after being sold is 0.1, it is expected that 10% (5.3) of 53 will be installed. Installation diffusion coefficient J for the second month
Since (t) is 0.15, it is expected that 7.95 of 53 units will be installed during this period. Similarly, the number of units installed after the third month is calculated.

The same calculation is performed for the main unit sales record planned number x (t) of each month. Then, in each month, the cumulative number of installed units is obtained by accumulating the number of installed units.

Then, an arbitrary fixed point is determined. For example, 6
The moon is the fixed point. 6 of main unit sales record y (t) in June
8 is smaller than the cumulative installed number of 111.1. this is,
This means that the actual number of machines in operation has not kept up with the forecast number. Next, the cumulative number of vehicles is shifted by one month in the future direction to make a temporary cumulative number of vehicles. The provisional cumulative number of vehicles in June is 66.4.
5, the main unit sales record number y (t) of 68 has caught up with the cumulative number (predicted number) of 66.45.
One month, which is this shift amount, is defined as a time difference (delay coefficient) d.

X with a time difference d obtained from the main unit sales record number x (t) and the main unit operation record number y (t)
Shift (t) in the future direction (direction in which t increases).
By executing the following prediction process with the shifted value as x (t) again, more accurate prediction is possible. It goes without saying that the processing for calculating the time difference d and the shifted x (t) is performed by the CPU 101 based on a program.

The shifted x (t) is hereinafter defined as the number of installed units.

[Step m3a2] Residual rate function calculation step / predicted main machine operating unit calculation step (prediction method 1)
(S810) The residual rate function S (t) is calculated. The residual rate function S (t) is a function indicating the ratio of the number of operating main bodies after t months to the number of installed main bodies. The survival rate is 1 when all installed main units are operating, and the remaining rate is 0.5 when half of the installed main units are operating.
Becomes

FIG. 5 is a diagram showing the residual rate function at the time of installation A, installation B, and installation C.

The horizontal axis of FIG. 5 represents time t, and the vertical axis represents the residual rate. The idea of the method of predicting the number of operating machines here is that the same main body model (prediction processing unit) at the same base remains at the "same" remaining rate regardless of the time of installation. That is, the installation time A, the installation time B, and the installation time C are installed at different times, but the remaining rate function is common.

Therefore, the operating number of main bodies at t is
It is the total of the remaining number of installed units before that. This relationship holds even when the sales volume is planned. Therefore,
The actual operating number of main bodies y (t) at time t is expressed by the following equation.

[0084]

[Outside 2]

E (t) is the error at time t. Main unit operating record y (t) and main unit sales record planned x
Since (t) is known up to the effective number T, the error e
Se indicating the sum of squares of (t) is expressed as follows.

[0086]

[Outside 3]

Then, the residual rate function S (t) that minimizes the error sum of squares Se is analytically or numerically obtained. In many cases, it is difficult to analytically obtain the residual rate function S (t) from Equation 3, and normally, for example,

[Outside 4]

The constants ω and r are obtained by numerical calculation. In that case, the residual rate function S (t) is not limited to the above-mentioned function, and may be any function as long as it is a function suitable for the target model.

The above processing is performed by the CPU 1 according to the program.
It is realized by 01 as follows. That is, the CPU
Reference numeral 101 denotes the above equation (3) based on the actual operation number y (t) of the main body, the remaining rate function S (t), and the actual operation number x (t) of the main body stored in the RAM 106.
Set on M106. Then, the step size t required for the numerical calculation is set, and S (t) is calculated by the numerical calculation so that the error sum of squares Se becomes minimum when the calculation is performed from time 0 to T. FIG. 6 is a diagram showing the relationship between the number of installed main bodies and the number of operating main bodies.

The line indicated by the broken line in the figure indicates the actual number of main body operation y (t). In addition, the starting point of the line that gradually decreases while each month is the starting point is the number of units installed in each month. The residual rate function S (t) that minimizes the error sum of squares Se is obtained based on Equation 3, and the residual rate function S
The remaining number of units can be obtained from (t) and the main unit sales record planned number of units x (t).

According to this prediction method (prediction method 1), it is possible to make highly accurate and stable prediction when there is a sufficient number of main body sales record planned quantity x (t).

[Step m3a3] Death probability density function calculation step (prediction method 1) (S811) Death probability density function f (t) is obtained. The death probability density function is obtained by differentiating the cumulative death function (F (t) = 1-S (t)) with respect to time and is given by the following equation.

[0093]

[Outside 5]

The CPU 101 calculates the residual density function S (t) based on S (t) stored in the RAM 106 and calculated in [step m3a2]. This death probability density function f (t) is a function indicating the disappearance probability of the main body in the market.

[Step m3a4] Average Life, Standard Deviation, Variation Coefficient Calculation Step (Prediction Method 1) Average life μ, standard deviation σ of average life, and variation coefficient φ of average life are obtained.

[0096]

[Outside 6]

[0097]

[Outside 7]

[0098]

[Outside 8]

The average life μ, the standard deviation σ of the average life, and the variation function φ of the average life are the death average density function f stored in the RAM 106 by the CPU 101.
It is sequentially calculated based on (t). These values are values indicating the disappearance status of the main body, and are used for development, production, sales, etc.

FIG. 16 is an example showing changes in the residual rate function when the average life μ and the variation coefficient φ are changed.

It can be seen that the larger the average life μ which is the horizontal axis in the figure, the longer the life of the main body.

It can be seen that the larger the coefficient of variation φ, which is the vertical axis in the figure, the flatter the remaining rate function and the more gradually disappears. On the other hand, it can be seen that the smaller the coefficient of variation φ, the steeper the change in the survival rate function, and the more suddenly it disappears at some point.

As described above, by examining the average life μ and the coefficient of variation φ, it is possible to evaluate the performance of the main body (how it disappears), the time of introduction of a new product, the time of replacement, and the like. Yes, strategic business is possible.

The features of the present invention will be described again below. The present invention is characterized in that it is not a forecast of “sales number” but a forecast of “operating number”. This is effective in a business (a business targeting the aftermarket) that makes a profit from maintenance after selling the main body such as a printer or a copier.

[Step m3b1] Death Probability Density Function Calculation Step (Prediction Method 2) (S812) Normally, if the number of data of the planned sales volume of main body x (t) is not sufficient, the accuracy and stability of the prediction are not good. . In this case, the above-mentioned death probability density function is obtained from preset parameters.

The parameters necessary for calculating the death probability density function are the average life μ and the coefficient of variation φ of the average life (or the standard deviation σ of the average life). These parameters are described in A. B. C. It is input by either method of.

Further, the planned sales volume x (t) of the main body is shifted (corrected) in the future direction by the delay coefficient d, and the number is set again as x (t).

The delay coefficient d is also the same as in the above A. B. C. It is input by either method of.

Then, the CPU 101 inputs the RAM
Based on μ, φ (or σ) stored in 106, the death probability density function f (t) is calculated numerically from Equations 4 to 7.
Ask for.

[Step m3b2] Remaining Rate Function Calculation Step (Prediction Method 2) (S814) As is clear from Equation 4, the CPU 10 is calculated using the following equation.
1 is the survival rate function S from the death probability density function f (t)
Find (t).

[0111]

[Outside 9]

S (0) = 1 (Equation 9) [Step m4] Step of calculating the main body operation predicted number (S8)
14) As is clear from equation 1, the number of main unit operation forecasts

[Outside 10]

Is as follows.

[0114]

[Outside 11]

FIG. 6 is a diagram showing the relationship between the number of installed main units and the predicted number of main unit operations / actual unit actual operation numbers.

The line shown by the broken line in the figure indicates the actual number of operating main bodies y (t). Further, the starting points of the lines that are decreasing and extending in each month are the number of installed units x (t).
The CPU 101 takes the sum of the remaining numbers of vehicles for each month and sets the sum as the predicted number of operating main bodies for each month. In the figure, it is indicated by a one-dot chain line.

[Step m5] Various Coefficient Calculation Steps The CPU 101, based on various parameters stored in the RAM 106, the reliability coefficient h for predicting the operating number of main bodies, the standard error s, the disappearance date Ed in the market, and the aging. The coefficient Ag is calculated.

[0118]

[Outside 12]

Normally, the prediction reliability coefficient h is not calculated in the forced prediction mode.

The prediction reliability coefficient h is an index indicating the stability / accuracy of the prediction model, and when the value exceeds 1, a stable prediction result is obtained.

The standard error s is calculated by the following equation.

[0122]

[Outside 13]

The standard error s is an index showing the prediction accuracy, and the smaller the value, the better.

The disappearance date Ed in the market represents the time (year / month) at which the main body will disappear from the market in the prediction model. Expiration date is the estimated number of operating units

[Outside 14]

It is the time when becomes 0, but instead of the time when it becomes 0

[Outside 15]

The time when the value becomes less than a certain threshold may be set as the extinction time.

The aging coefficient Ag is calculated by the following equation.

[0128]

[Outside 16]

C is the time corresponding to the time when the prediction process is executed. This value is an index showing the state that the main body is "aging" in the market. Immediately after the main body is put on the market, the aging coefficient Ag is 0, and when the main body disappears from the market, the aging coefficient Ag is 1.

The aging coefficient Ag is an important index for representing the operating status of the main body in the market.

[2. Prediction of Average PV (Print Volume) of Main Body (Average PV Prediction Block)] FIG. 9 is a diagram showing a processing flow when predicting the average PV of the main body.

The constants, variables and functions used in this processing block are as follows. t: A unit time (for example, month) at which the data is observed, where the start date of the main body sale is 0 as the starting point. p (t): average PV performance of t months q (t): average PV dummy of t months v (t): average PV performance dummy of t months

[Outside 17]

R: Multiple correlation coefficient s: Standard error [step p0] Average PC performance dummy calculation step (S
902) The CPU 101 generates an average PV actual result dummy v (t) based on the following equation from the average PV actual result p (t) and the average PV dummy q (t) which are input and stored in the RAM 106. (Equation 14) if p (t) = null then v (t) = q
(T) if p (t) ≠ null then v (t) = p
(T) The average PV performance p (t) can be obtained by the service engineer visiting and confirming the customer. Average PV
The dummy q (t) is set in advance when the data cannot be trusted even when there is no actual result or when the actual result exists. The average PV is the number of prints per unit time per unit. In the present embodiment, the unit time is a monthly unit, but an annual unit, a week unit,
Needless to say, it does not matter if it is on a daily basis.

[Step p1] Target base / target model selection step (S903) Similar to step m1, a base and a main model (prediction processing unit) for which prediction processing is to be executed are selected. A plurality of prediction processing units may be selected. This selection is realized by the "input" described above.

[Step p2] Average PV Actual / Average PV
Dummy reading step (S904) Similar to step m2, average PV stored in time series
The actual result p (t) and the average PV dummy q (t) are read for each prediction processing unit. That is, the input average PV performance p
(T) and the average PV dummy q (t) are stored in the RAM 106.

[Step p3] Average PV Prediction Step (S905) The average PV prediction has the following three modes. (1) Prediction mode 1: The average PV actual result p (t) is subjected to nonlinear regression. (2) Prediction mode 2: Non-linear regression is performed on the average PV dummy q (t). (3) Prediction mode 3: The average PV performance dummy v (t) is subjected to nonlinear regression.

From the above three prediction modes, the most suitable prediction mode is selected in consideration of data reliability and the like. This “selection” may be performed by the user via the input unit 102, or may be performed by the CPU 101 based on a certain condition (for example, the number of data items).

As an example, the case of the prediction mode 3 will be described. The average PV actual result dummy v (t) is defined as the following model formula.

[0139]

[Outside 18]

It goes without saying that the model formula is not limited to the equation (15). e (t) is the error at time t.
If T is the effective number of v (t), the error sum of squares Se is

[Outside 19]

The coefficients b, r, and a are determined so that the error sum of squares Se is minimized. The CPU 101 uses the numerical analysis (for example, the least squares method) to calculate the coefficient b,
Find r and a. And the average PV prediction from the obtained b, r, a

[Outside 20]

Is as follows.

[0143]

[Outside 21]

Needless to say, linear regression may be used depending on the model.

[Step p4] Multiple Correlation Coefficient, Standard Error Calculation Step In order to evaluate the non-linear regression (linear regression) in step p3, the CPU 101 calculates the multiple correlation coefficient based on various parameters stored in the RAM 106. R and standard error s are calculated using the following formula.

[0146]

[Outside 22]

[0147]

[Outside 23]

(Equation 19)

[Outside 24]

[3. Prediction of Total PV of Main Body (Total Predicted PV Block)] FIG. 10 is a diagram showing a processing flow when predicting total PV of the main body.

The constants, variables, and functions used in this processing are as follows. t: Unit time (for example, month)

[Outside 25]

[0151]

[Outside 26]

The above calculation is performed by the CPU 101 in the RAM.
It is realized based on the above-mentioned parameters stored in 106.

[Step s2] Aging Coefficient Calculation Step (S1003) The CPU 101 obtains the aging coefficient Ag in consideration of PV using the following formula.

[0154]

[Outside 27]

C is the time (year / month) of the predicted processing day converted into an address. The value of the aging coefficient Ag is PV
Is an index showing the state of aging in the market with the main body added, and if it is in the state of being born in the main body, the aging coefficient Ag
Is 0, and when it disappears from the market, the aging coefficient Ag becomes 1.

[4. Consumables Demand Forecast (Consumables Prediction Block)] FIG. 11 is a diagram showing a processing flow when the consumables demand is predicted.

The constants, variables, and functions used in this processing are as follows. t: Unit time (for example, month) z (t): Sales record of consumables for t months

[Outside 28]

T: Actual period when observed data is 0 ≦ t ≦ T, actual when T ≦ t, C: predicted number of sheets H: diffusion range (delay width) p (i): diffusion density function ( 0 ≦ i ≦ H) u (i): Seasonal coefficient of variation (0 ≦ i ≦ 11) Ed: Extinction time Ag: Aging coefficient R: Multiple correlation coefficient s: Standard error [step k1] Target base / target model selection step (S1102) A base and a consumable item model for performing the prediction process are selected. There may be a plurality of locations and consumable item models selected.
This "selection" is based on the above-mentioned A. B. C. It is realized by any one of the input methods.

FIG. 7 is a diagram showing the correspondence between and the consumable model.

[0160] "O" in the figure indicates that the consumable model is sold at the site.

[Step k2] Sales record of consumables / total PV
Prediction reading step (S1103) Consumable sales record z (t) accumulated in time series and total PV prediction of the main body using the consumable.

[Outside 29]

Is input for each consumable model and one site (consumable prediction processing unit) and stored in the RAM 106. If the consumable you are looking for is used in multiple units, the total PV forecast for each unit

[Outside 30]

Resuming the sum of

[Outside 31]

It is assumed that

For example, in FIG. 2 and FIG. 7, when the copier A (201) and the printer B (202) use the common toner C (701) in Japan, the base of the consumables prediction processing unit is Japan, Product model is Toner C, total PV forecast

[Outside 32]

Is the total PV forecast of copy machine A in Japan.

[Outside 33]

And total PV prediction of printer B

[Outside 34]

It is the sum of

[Step k3] Prediction Mode Control Step (S1104) One prediction method is selected from the following two prediction methods as in the case of predicting the number of operating main bodies. (Prediction method A) Execute steps k3a1 and k3a2 (Prediction method B) Prediction mode A, which executes step k3b1, requires a certain number of actual data, and is not suitable when the data is small.
The prediction method of is often suitable. Although this prediction method may be set in advance (forced prediction mode), the prediction method may be automatically selected (automatic prediction mode) as follows.

That is, when the number of valid cases T is greater than or equal to a certain threshold value N, the prediction method 1 is selected assuming that the prediction method 1 has sufficient data. On the other hand, when the number of valid cases T is less than the threshold value N, prediction is performed. Judging that Method 1 does not have enough data,
The prediction method 2 is selected (S1105). This judgment is C
It is realized by the PU 101.

For example, assuming N = 24, if the number of valid cases T is 24 or more, the prediction method 1 is selected, and if the number of valid cases T is less than 24, the prediction method 2 is selected.

In the above example, the prediction method is selected according to the number of valid cases T, but the prediction method may be selected using another parameter.

The prediction method 2 is often selected when sufficient data cannot be obtained or during simulation at the sales planning stage.

As in the case of predicting the number of operating main bodies, it is said that the prediction method 1 has higher prediction accuracy than the prediction method 2. However, in some cases, the prediction method 2 may be more accurate than the prediction method 1 even when there is sufficient data. In such a case, the forced prediction mode will be selected.

[Step k3a1] Consumable item sales record smoothing step (S1106) The consumable item sales record z (t) is smoothed. CPU 101
Is the consumable sales record z stored in the RAM 106.
Smoothing is realized by multiplying (t) by a moving average (for example, a moving average of 12 months). Let the smoothed consumable item sales record z (t) be the new consumable item sales record z (t). This smoothing is for absorbing fluctuations due to errors and seasonal fluctuations, and thus the method is not limited to applying a moving average as long as it is a method capable of smoothing.

[Step k3a2] Endurance Number / Diffusion Coefficient Calculation Step 1 (S1107) Smoothed Consumables Sales Record z (t) and Total PV Prediction

[Outside 35]

From the number of durable sheets C per unit time and the diffusion density function p (t) are obtained from the following. The number of durable sheets is PV that can be taken per unit in a unit time, and the diffusion density function p
(T) is the probability density of the consumable goods sold during the time H (diffusion range, delay width) before a certain time, consumed during the time H.

In the consumables prediction model here,
It is assumed that the durable number C of the same consumable model at the same location is constant at any time and follows the same diffusion density function. This assumption is one feature of the present invention.

Therefore, the predictive model of the consumable item is expressed by the following equation.

[0180]

[Outside 36]

Here, p (t) is a probability density function. p
(T) is defined in the interval 0 ≦ t ≦ H,

[Outside 37]

And, p (t) ≧ 0 (Equation 25) is satisfied. Further, e (t) is an error at time t. The error sum of squares Se, which indicates the sum of squares of the error e (t), is expressed as follows.

[0183]

[Outside 38]

The number of durable sheets C and the diffusion density function p that minimize the error sum of squares Se under the conditions of Eqs.
(T) is obtained by numerical analysis by the CPU 101. At this time, the diffusion range (delay width) H is assumed to be input in advance.

[Step k3b1] Endurance Number / Diffusion Coefficient Setting Step (S1109) When the number of data of sales record z (t) of consumables is small,
Since it is difficult to obtain the stable durable sheet number C and the probability density function p (t), the durable sheet number C and the diffusion density function p are calculated in advance.
(T) and diffusion range (delay width) H are input.

[Step k4] Consumables Sales Forecasting Step (S1110) Consumables Sales Forecasting (Demand Forecasting)

[Outside 39]

[0187]

The number of durable sheets C found in step k3a1,
Diffusion density function p (t) and diffusion range H, or durable sheet number C set by step k3b1, diffusion density function p
Substituting (t) and the diffusion range H into the equation 23, z (t) is sequentially determined so that Se is minimized.

[0189] Forecast the sales of the consumables

[Outside 40]

It is assumed that

[Step k5] Seasonal Fluctuation Correction Step (S1111) Correction processing based on seasonal fluctuations is performed. In the example of the image forming apparatus according to the present embodiment, the term “seasonal fluctuation” means that the sales volume fluctuates depending on the season, such as a large print volume during the Christmas season or the settlement period.

First, it is determined whether or not seasonal fluctuation correction is performed. This judgment is made under certain conditions of the CPU 101 (for example,
It may be realized by paying attention to the number of data of a certain parameter stored in the RAM 106, or the user may determine this determination via the input unit 102. If it is determined that seasonal fluctuations occur, sales forecasts for consumables considering seasonal fluctuations are made, but if it is determined that seasonal fluctuations do not occur, sales forecasts for consumables considering seasonal fluctuations are not made.

When the sales forecast of consumables in consideration of seasonal variation is performed, the following processing is performed.

When the seasonal variation is considered, the seasonal variation coefficient u
It is necessary to determine (i). This seasonal coefficient u
(I) is calculated from the performance data, but may be input in advance. It is appropriately selected whether the seasonal variation coefficient u (i) calculated from the actual data is used or a preset value is used. This selection is CPU1
01 may be automatically performed based on a certain condition, or may be input. The selection method has the following two modes.

(1) The number T of effective cases stored in the automatic calculation mode RAM 106 is the same as R
Threshold value N stored in AM 106 (eg N = 24)
In the above cases, the seasonal variation coefficient is calculated from the actual data. The maximum natural number n that satisfies 12n ≦ T is found from the latest time data, and the seasonal variation coefficient is obtained from the data from time T-12n + 1 to T. Here, for convenience, T-1
It is assumed that 2n + 1 is the starting point 0 and T is 12n-1.

The CPU 101 obtains the fluctuation rate g (t) from the cycle stored in the RAM 106 using the following formula.

[0197]

[Outside 41]

When the seasonal variation is extracted, the magnitude of the variation fluctuates greatly when the absolute amount of the month is large, and changes small when the absolute amount is small. For example, the sales volume (basic demand) is 100 in January 2000 and 10 in January 2001.
When it is 00, the variation amount often changes to 10, 100 accordingly, so it is better to capture it by the variation rate. In this example, both 10/100 and 100/1000 are 0.1. Therefore, in the case of extracting periodic fluctuations, it is often more realistic to capture the fluctuations so as not to depend on the magnitude of the absolute amount (normalization). Therefore, normalization is performed by removing the trend value (basic demand) from the observed value and dividing it by the trend value. Then, the CPU 101 obtains the seasonal variation coefficient u (i) by the following formula.

[0199]

[Outside 42]

The above equation finds the average of the volatility for each month. For example, the coefficient of variation for May is May 1998, 1999
The average of the volatility in each month from January to December, such as the average of the volatility in May and May 2000 of the year, is obtained and used as the seasonal coefficient of variation. Since the fluctuation rate is calculated in (Equation 27) so as not to depend on the absolute amount, it makes sense to take an average, and the accuracy is further improved by taking the average. However, 0 ≦ i ≦ 11 (Equation 29). Sales forecast after seasonal fluctuation correction

[Outside 43]

Is calculated by the following equation.

[0202]

[Outside 44]

The above formula is a formula for multiplying the sales forecast (trend value, basic demand amount) by the seasonal variation coefficient of each month to obtain the sales forecast in consideration of the seasonal variation. This calculation is realized by the CPU 101.

For example, the sales forecast for May 2000 is 20.
The sales forecast for May 2000 is multiplied by the seasonal variation coefficient for May to obtain a value that takes seasonal variation into account.

Note that mod (t, 12) represents the remainder when t is divided by 12. Found

[Outside 45]

Anew

[Outside 46]

It is assumed that

On the other hand, when the number of valid cases T is less than a certain threshold value N, u (i) is set as a predetermined seasonal coefficient of seasonal variation for i + 1 month. The value after seasonal fluctuation correction is given in advance u
Equation (30) using (i)

[Outside 47]

Renewing

[Outside 48]

It is assumed that

(2) Forced mode In the automatic calculation mode, whether to calculate the seasonal variation coefficient or to use the one given in advance was automatically determined, but it is inconvenient if it is automatically determined. There are cases. In this case, it is determined in advance whether to calculate the seasonal variation coefficient or to use the one given in advance in this forced mode.

As described above, by making it possible to select the automatic calculation mode or the forced mode, more flexible and agile prediction becomes possible.

[Step k6] Various Coefficient Calculation Steps Next, the CPU 101 obtains the expiry date Ed of the consumables, the aging coefficient Ag, the multiple correlation coefficient R, and the standard error s based on the various parameters stored in the RAM 106. .

The disappearance time Ed is

[Outside 49]

This is the time (year / month) when is zero. This represents the time when there will be no demand for consumables on the market.

[0216]

[Outside 50]

Instead of 0, the time when the demand becomes less than a certain threshold can be set as Ed.

The aging coefficient can be calculated by the following formula.

[0219]

[Outside 51]

C is an address corresponding to the time when the prediction process is executed. This is an index showing how much of the consumables market is currently in demand.
When the aging coefficient Ag is 0, it indicates that no demand is generated at this moment, and when the aging coefficient Ag is 1,
At this point, the demand has already ended.

The multiple correlation coefficient R is obtained by the following equation.

[0222]

[Outside 52]

It should be noted that

[Outside 53]

[0224] The multiple correlation coefficient R is an index indicating the prediction accuracy, and the closer to 1 the accuracy is, and the closer to 0 the accuracy is.

The standard error s is obtained by the following formula.

[0226]

[Outside 54]

The standard error s is an index showing the prediction accuracy, and the closer to 0, the better the accuracy.

In the present embodiment, the unit time is a month, but it may be a year unit, a day unit, or a week unit. Further, the process may not be performed every unit time, but may be performed at any time. That is, the processing may proceed at indefinite intervals such as 1 month → 2 months → 1 month → 3 months.

As described above, according to the present invention, it is possible to support the planning of the consumables business based on the demand forecast result of the consumables.

[5. Display of Prediction Result] The above-mentioned prediction result of the number of operating main bodies and demand prediction result of consumables are the CPU
Under the control of 1, the information is displayed on the output unit 103 in a table format and / or a graph format.

FIG. 36 shows a screen when the demand forecast result of consumables is displayed on the output unit 103.

Similarly, various coefficients (for example, reliability coefficient h,
The disappearance date Ed, the aging coefficient Ag, etc.) are also output by the output unit 10.
Needless to say, it may be displayed in 3.

[6. Switching of prediction method] Conventional prediction method,
Also, in the above forecasting method, a single forecasting method is used over the entire sales period of the product, so if the sales demand fluctuates due to causes not anticipated by the forecasting method, the accuracy of the sales forecasting Was sometimes reduced.

Particularly, in the following three points, it was difficult to realize accurate prediction by the conventional prediction method. A. In the industry such as pipeline fill office machines and consumables for peripherals of personal computers, there are many cases where intermediate wholesalers and dealers have inventory because they are obliged to reliably supply consumables to end users. The demand to meet those inventories is commonly called pipeline fill. Due to this pipeline fill, a characteristic demand that cannot be predicted by the conventional prediction method is generated in the early stage of sales. B. Appearance of compatible products In the industry such as consumables for office machines and PC peripherals, in addition to consumable products manufactured by the main makers of office machines, compatible products manufactured by other manufacturers that are compatible with this have appeared. There is a case. In this case, the sales of consumables manufactured by the main body manufacturer may be affected. The conventional prediction method cannot sufficiently predict the appearance of such compatible products. C. End of consumables sales period Consumables for office machines and PC peripherals need to be sold for as long as the user continues to use the main unit even after the main unit has been sold. At the end of the period, the sales of consumables may become unstable due to the distribution of second-hand items for office machines and computer peripherals outside the markets envisioned by the manufacturer. Conventional forecasting methods have not been able to accurately forecast the end of such a sales period.

The present invention was created to solve the above problems. The details will be described below with reference to the drawings.

FIG. 18 is a conceptual diagram of demand forecast of consumables.

In the figure, the transition of the sales record and the demand forecast of the consumables at a certain point are shown. Hereinafter, the “consumable item” will be described, but this may be a “product”.

FIG. 19 is a conceptual diagram of initial demand forecast for solving the problem of pipeline fill (A).

As can be seen by looking at the sales record in FIG.
The sales quantity behaves differently in the initial period of sale than in other periods.

FIG. 20 is a conceptual diagram of another-company reflected demand forecast for solving the problem of appearance (B) of compatible products.

As can be seen from the sales record in FIG. 20,
It can be seen that the sales volume deviates from the initial demand forecast at some point (the appearance of compatible products).

FIG. 21 is a conceptual diagram of trend demand forecast for solving the problem at the end of the sales period.

As can be seen from the sales record in FIG. 21,
At the end of the sales period, the behavior deviates from the initial demand forecast.

FIG. 23 shows a module structure added to the module structure of the program of FIG. 17 for switching the prediction method.

[Consumables Demand Forecasting Module (230
3)] This module executes the demand forecasting method for the main body and consumables described above and the demand forecasting using a simple linear (non-linear) approximation. Consumables demand forecast module (503)
It is assumed that the latest prediction results are always accumulated.

[Consumables Initial Demand Forecast Module (230
4)] It is a module that realizes a consumable product initial demand forecast (F2) for solving the pipeline fill problem of FIG.

The consumable goods initial demand module is realized based on the following two models.

(Model 1) For the fixed period (specified by the consumables initial demand forecasting model master) from the month when the main body accompanying model is sold, it is designated by the consumables initial demand model master for the main unit sales result plan (RPM) Multiply the coefficient and use the prediction result.

(Model 2) Demand Forecast Proportional Model Consumables demand forecast results (FC
1) is multiplied by the coefficient specified in the consumables demand model master, and the prediction result is adopted.

[Consumables Demand Reflection Module Reflected by Other Company (2
305)] It is a module that implements a consumable product other-company reflection prediction (F4) for solving the problem of appearance (B) of a compatible product in FIG.

The consumables company reflected demand forecast is a prediction in which the consumables demand forecast result (FC1) is multiplied by a consumables company reflection coefficient and the calculation result is used as the forecast result. The target period is determined as follows.

[0252] From the first month in which the consumables sales record (RC) is present, the period after the period (number of months) of the forecast model master for reflecting other companies has passed and the period for which the consumables other company reflects forecasting period (T (FC5)).
And

FIG. 36 is a diagram showing an example of the consumables sales record (RC) and the consumables other-company reflected prediction target period (T (FC5)).

In the example of FIG. 36, since the sales record has been available since March 1999, the target period starts from February 2001, which is the 24th month.

The consumables other company reflection coefficient is arbitrarily set in advance in the other company reflection model master.

[Consumables Trend Demand Forecasting Module (2
305)] This module realizes a consumable product trend demand forecast (F3) for solving the problem at the end of the sales period in FIG.

In the consumables demand trend prediction, the demand is calculated by performing a non-linear regression analysis or the like on the sales results of the consumables itself on the time axis without using the causal relationship with the total PV prediction used for the consumables demand prediction. Predict.

The target consumables are those for which the main body has been almost sold, or consumables designated arbitrarily.

[Determination Module (2307)] Which demand forecast result is suitable for the latest performance is determined.
The difference between the latest past n months of actual results and each demand forecast is calculated, and the demand forecast with the smallest difference is selected.

FIG. 24 is an overall flow chart of the present invention.

The consumable product demand forecasting process of S2401 in the figure is performed by the above-mentioned [1. Prediction of the number of operating main units] [2. Prediction of average PV of main body] [3. Prediction of total PV of main body] [4. Consumables demand forecast].

FIG. 25 is a flow chart showing details of the consumable goods initial demand forecasting process of S2402 of FIG.

In S2501, the CPU 101 calls the initial demand consumable goods base / cross master MC from the consumable goods initial demand cross master DB (DB (F)) RAM1.
Write to 06.

In S2502, the CPU 101 calls the consumable product initial demand model master MI1 designated by MC from the consumable product initial demand model DB (DB (G)) and writes it in the RAM 106.

[0265] In S2503, the CPU 101 calls the main body sales performance plan RPM from the main body sales schedule / performance DB (DB (H)) and writes it in the RAM 106.

In S2504, the CPU 101 executes the initial demand forecast (F2).

In S2505, the initial demand forecast (F
The result of 2) is the consumables initial demand forecast result DB (DB
(C)) Write in the area of the consumables initial demand forecast result FC3.

FIG. 26 is a flow chart showing the details of the consumables company reflected demand forecasting process of S2403 of FIG.

In S2601, the CPU 101 calls up the consumables company reflected site / cross master MC4 from the consumables company reflected cross master DB (DB (K)) to execute RA
Write to M106.

[0270] In S2602, the CPU 101 reads the MC from the model master DB (DB (L)) reflecting the consumable product of another company.
Consumables Specified in 4 Other company reflected prediction model master MI
2 is written and written in the RAM 106.

In S2603, the CPU 101 calls the consumables sales record (RC) from the consumables sales record DB (DB (D)) and writes it in the RAM 106.

[0272] In S2604, in the RAM 106,
Create a forecast period (T (FC5)) for reflecting the consumables company.

[0273] In S2605, the CPU 101 determines whether or not it is the target period of the consumables company reflected demand forecast. Specifically, the period for which the consumable product is reflected in another company's demand forecast (T (FC
5)) If there is no sales record (RC) of consumables in S, S
Proceeding to 2606, the demand forecast result DB (D
All of "0" is written in the area of the demand forecast result FC5 of the consumable product reflected by another company of B (M)).

Also, in S2605, the CPU 101
However, if it is determined that there is a consumables sales record within the consumables reflected demand forecast period, the process proceeds to S2607, and the consumables demand forecast result (before correction) (DB (A)) is calculated. Before) (FC1) is called and written in the RAM 106.

[0275] In S2608, the CPU 101 executes the consumables company reflected demand forecast (F4).

[0276] In S2609, the CPU 101 writes the result of the consumables company reflected demand forecast (F4) in the area of the consumables company reflected demand forecast result F5C of the consumables company other demand forecast result DB (DB (M)).

FIG. 27 is a flow chart showing details of the consumable goods trend demand forecasting process of S2404 of FIG.

In S2701, the CPU 101 calls the main body sales result (RM) and the main body sales result plan from the main body sales schedule / actual result DB (DB (H)), and the RAM 1
Write to 06.

[0279] In S2702, the CPU 101 writes the consumable goods trend prediction target item in the RAM 106 from the consumable goods trend demand prediction item DB (DB (I)).

[0280] In S2703, the CPU 101 determines whether or not it is the consumable goods trend prediction period. Specifically, when the sum of the main body sales results divided by the sum of the main body sales performance plans is equal to or greater than an arbitrary value (0.90 in FIG. 27), the consumable product trend demand forecast period is set. .

Also, in S2703, there is a request for the user to forcibly execute the consumable goods trend demand prediction even during the consumable goods trend demand prediction period. Therefore, in S2704, it is determined whether or not the consumable goods trend demand prediction item DB (DB (I)) exists, and if it exists, the process forcibly proceeds to S2709.

On the other hand, if the consumables trend demand forecast item DB (DB (I)) does not exist in S2704, the process proceeds to S2705, and the consumables trend demand forecast result DB (DB (M)) is reflected by the other companies. Demand forecast result FC
Write "0" in all of the 5 areas.

In S2706, the CPU 101 calls the consumables sales record (RC) from the consumables sales record DB (DB (D)) and writes it in the RAM 106.

[0284] In S2707, the CPU 101 executes consumable product trend demand forecast (F3).

[0285] In S2708, the CPU 101 writes the result of the consumable goods trend demand prediction in the area of the consumable goods trend demand prediction result FC4 of the consumable goods trend demand prediction result DB (DB (I)).

28 and 29 show S2405 of FIG.
7 is a diagram showing a flow of determining a prediction method in S2407 and S2407.

[0287] In S2801, the CPU 101 causes the consumable goods demand prediction module to calculate the consumable goods demand prediction result (FC
1) is called and written in the RAM 106 and the consumables demand forecast result (corrected) DB (DB (B)).

[0288] In S2802, the CPU 101 causes the consumables demand forecast result (FC
3) is called and written in the RAM 106.

In S2803, the CPU 101 calls the consumables company reflected demand forecast result (FC5) from the consumables company reflected forecast module and writes it in the RAM 106.

[0290] In S2804, the CPU 101 calls the consumable goods trend prediction result (FC4) from the consumable goods trend prediction module and writes it in the RAM 106.

In S2805, the CPU 101 calls the consumables sales record (RC) from the consumables sales record DB (DB (D)) and writes it in the RAM 106.

[0292] In S2806, the CPU 101 determines whether or not there is a consumable product sales record. Specifically, if the consumable product sales record period (T (RC)) is greater than 0, the process proceeds to S2807, and if not, S2809.
Move to.

[0293] In S2807, the CPU 101 determines whether or not the consumable product sales record period is less than or equal to the initial demand forecast period. Specifically, the initial demand forecast period (T (FC3))
Is the consumables sales record period (T (RC)) or more, S
If not, the process proceeds to S2910 of FIG. 29, which will be described later.

At S2808, the CPU 101
It is determined whether or not the difference between the initial demand forecast result and the consumable item demand forecast result is smaller than the consumable item sales record. Specifically, the absolute value of the difference between the consumables demand forecast result and the consumables sales record result for the past n months (n is arbitrary) is the absolute difference between the consumables demand forecast result and the consumables sales record result. It is determined whether it is smaller than the value. The CPU 101 determines that the absolute value of the difference between the consumables demand forecast result for the past n months and the consumables sales result result is
If it is determined that it is smaller than the absolute value of the difference between the consumable goods demand prediction result and the consumable goods sales result result, the operation proceeds to S2809, and if not, the operation proceeds to S2910 of FIG. 29 described later.

[0295] In S2890, the CPU 101 writes the consumable goods initial demand prediction result (FC4) in the consumable goods demand prediction result (corrected) DB (DB (B)) consumable goods demand prediction result (FC2).

In S2910 of FIG. 29, the following A,
Of B and C, the one having the smallest absolute value of the difference is determined.

A. Absolute value of the difference between the consumables demand forecast result and the consumables sales result result in the past n months B. Absolute value of the difference between the consumables trend demand forecast result for the past n months and the consumables sales result result C. Absolute value of the difference between the forecast results of consumables reflected by other companies in the past n months and the results of sales of consumables B. Is the smallest, the process proceeds to S2911, and the consumable goods demand forecast result (FC4) is written to the consumable goods demand forecast result (corrected) DB (DB (B)) consumable demand forecast result (FC2). If C is the smallest,
After shifting to S2912, the demand forecast result (F
C3) is the consumables demand forecast result (after correction) DB (DB
(B)) Consumables demand forecast result (FC2) is written.

The consumable goods trend prediction module (2305), which is one of the features of the present invention, will be described in more detail.

Consumables Trend Demand Forecasting Module (23
05) is a module that executes consumable goods trend demand forecast (F3). In this demand forecast, non-linear regression analysis is performed on the sales record of the consumable item itself on the time axis without using the causal relationship with the total PV forecast used for the consumable item demand forecast, and is used as the demand forecast.

The target consumables are those for which the main body has been almost sold, or the consumables designated arbitrarily.

As an example, the following model is used.

Y (t) = a exp (bt ^r ) y (t): Sales quantity of expendables in month t exp: exp function a: desired coefficient b: desired coefficient In order to apply a non-linear regression model, a prediction is made. The coefficient of the regression equation is determined so that the sum of squares of the residuals of the measured value and the measured value is minimized. As for the calculation formula at this time, general minimum time information is used, and thus the description thereof is omitted here. At this time,
There are the following two patterns for giving the period (start date, end date) of the sales performance data used for obtaining the coefficient.

CASE1 Start year / month: When the total sum of the main body results exceeds an arbitrary ratio with respect to the total sum of the main body sales performance plans End year / month: Until the year and month when the forecast data exists CASE2 Start year / month: User specifies End date: Until the year and month when the prediction data exists FIGS. 34 and 35 are diagrams showing various databases of the present invention.

FIG. 30 is a diagram showing the transition of the database at the time of forecasting the initial demand of consumables.

FIG. 31 is a diagram showing the transition of the database at the time of forecasting the demand reflected by another company of consumables.

FIG. 32 is a diagram showing the transition of the database at the time of the consumable goods trend demand forecast.

FIG. 33 is a diagram showing a transition at the time of determining the prediction method.

[0308] Note that all of the above processes are C shown in Fig. 1.
Needless to say, it is realized by the PU 101 or the like.

As can be seen by looking at the flow of FIGS. 24 to 35 and the transition of the database, the present invention can Pipeline fill, B.I. Appearance of compatible products, C.I. Attention has been paid to the characteristics of sales at the end of the sales period, and efforts have been made to minimize forecast errors that may occur due to these characteristics.

FIG. 22 shows a summary of these processes.

The present invention has the following effects. ○ Consumables demand forecast switching system Having an optimal demand forecast method for each sales period and selecting it makes it possible to carry out highly accurate production, sales, and inventory planning for each sales period. As a result, it is possible to hold an appropriate inventory without missing a sales opportunity. ○ Consumables Initial Demand Forecasting System By forecasting the demand to meet the inventory demand of intermediary wholesalers and retailers that occurs in the early stage of the consumables sales period, it is possible to retain appropriate inventory without missing sales opportunities. It will be possible. ○ Consumables Demand forecast system reflected by other companies In the industry such as consumables for office machines and PC peripherals, in addition to compatible products manufactured by office machine manufacturers, non-office machine manufacturers that are compatible with this There may be compatible products manufactured by. When a compatible product appears, by reflecting the influence on the demand forecast, it is possible to hold a proper inventory without missing a sales opportunity. ○ Consumables trend demand forecast During the sales period of consumables for office machines and PC peripherals, the main unit will continue to be used even after the sale of the main unit, so at the end of the consumables sales period A market where used machines of PC peripherals are assumed by the manufacturer
The distribution of consumables may become unstable due to distribution to other sources. In such a case, the future sales forecast is made based on the sales results of the consumables themselves. As a result, it is possible to hold an appropriate inventory without missing a sales opportunity.

[7. Consumables Macro Demand Forecast] In the conventional method of forecasting consumables, since forecasts are made for one market and one product,
If there are markets and products that affect each other, conventional forecasts cannot handle them.

When there are two products whose functions can be mutually replaced (eg, consumables for copier C3300, C33)
Case of 00 drum unit and C3300 unit drum) The photoconductor drum is a major consumable item that needs to be replaced when a peripheral device for a copying machine or a personal computer requiring maintenance work outputs a certain output. Further, in the copying machine or the peripheral equipment of the personal computer, there are replacement parts that need to be replaced in addition to the photosensitive drum.

In this embodiment, the C3300 drum unit can be replaced at the same time as the photosensitive drum and other replacement parts incorporated in the unit, so that the working time of the operator can be reduced. On the other hand, for the C3300 single-piece drum, the operator determines the wear level of each consumable item and replaces it, so that the cost of parts can be reduced.

Therefore, the C3300 drum unit and the C3
The total demand for 300 single-piece drums remains unchanged, and if the sales of one increases, the sales of one decreases.

Copying machine C330 to predict the demands of both parties
After making a demand forecast for the C3300 drum unit for 0 and the total of the C3300 single drums, the total demand forecast is divided from the actual results of the conventional model or the past results of the C3300 drum unit and the C3300 single drum itself, and divides them into the respective models. Demand forecast.

When predicting the demands of two markets that affect each other (Example: Case of copier C3300 and its consumable C3300 toner sold in Germany and Austria) One kind of copier or PC peripheral Even if the equipment is sold in two separate markets, the two markets may affect each other in consumables.
Copier C3 in the German and Austrian markets for example
When 300 and its consumables are sold, it is conceivable that dealers dealing with the consumables may procure the consumables without being aware of the border because of geographical and cultural proximity. In this case, the total demand of both parties does not change, and if the sales of one increase, the sales of one decrease. Therefore, after forecasting the demand for C3300 toner for both markets in order to forecast the demand for both, the actual results of the conventional model or C3300
Dividing the total demand forecast from Toner's own past performance,
Let it be the demand forecast of each market.

FIG. 37 is a diagram showing a conceptual diagram of consumables macro demand forecast. The consumables macro demand forecast will be described below with reference to FIG.

The graph (A) is a graph of the demand forecast of the sales area A. The graph (B) is a graph of the demand forecast of the sales area B.

In the sales area A and the sales area B, if the total of 1,000 copying machines are sold in exactly the same way and the demand forecast is made with the same parameters, the consumables in the graphs (A) and (B) are assumed. Both are exactly the same, as in the demand forecast graph.

However, in the case of markets that influence each other,
The total sales forecast quantity matches the sales record, but one sales record exceeds the sales forecast (Sales area B in the case of FIG. 37), and one is below the sales forecast (Sales area A in the case of FIG. 37). ) There are cases. That is, since the two influence each other, the demand forecast deviates from the sales forecast.

Therefore, the main body sales record of the sales region A and the sales region B, the consumable product sales record, the prediction parameter, and the like are summed up for prediction. Graph (C) is the result of making a prediction by adding together the various values of sales areas A and B.

After summing up and predicting, sales area A and
The consumables sales forecast is redistributed (divided) based on a predetermined ratio of the sales area B (the “predetermined ratio” will be described later).

Graphs (D) and (E) show the demand forecast graphs of the sales area A and the sales area B after the reallocation (division).

As is clear from comparing graphs (A), (B), (D), and (E), the prediction method in which the calculation is performed after the summation is performed realizes a very good prediction. be able to.

FIG. 38 shows the structure of a module for macro demand forecasting.

FIG. 39 is a schematic diagram of the flow of consumables macro demand forecast.

FIG. 40 is a detailed diagram of the flow of the consumables macro demand forecast.

In S4001, the CPU 101 calls the consumable product macro master (MM) from the consumable product macro master DB (DB (N)) and writes it in the RAM 106.

In S4002, the CPU 101 calls the consumables macro parameter (MP) from the consumables macro parameter DB (DB (R)) and writes it in the RAM 106.

[0331] In S4003, the CPU 101 calls the consumables sales record (RC) from the consumables sales record DB (DB (D)) and writes it in the RAM 106.

In S4004, the CPU 101 reads R
On the AM 106, the consumables sales record (z) is created from the consumables sales record (RC). By this operation, the sales results of two or more consumables are added up (for details, refer to FIG.
In step S4005, the CPU 101 predicts the demand for consumables.

[0333] In S4006, it is determined whether or not the consumable product sales record period is a predetermined period (1 year in Fig. 40) or more. If the sales period of consumables is more than a predetermined period,
In step S4007, the macro division ratio (mdr) is created based on the sales record of the consumable supplies of the macro target item itself. The macro division ratio will be described in detail below (three modes).

(1) Creating Macro Division Ratio (mdr) by Adopting Cumulative Sales Actuals FIG. 45 is a table showing the sales of consumables until October of a certain year.

Since the cumulative value up to October is 370 for the C2000 cartridge and 145 for the C4000 cartridge, the macro division ratio (mdr) is 370: 14.
It will be 5.

(2) Macro division ratio is created by weighting sales record. FIG. 46 is a graph showing weights to be added to the sales record. The weights shown in FIG. 46 are stored in the RAM 10 in advance.
It is written in 6th grade. The sales record of FIG. 45 is multiplied by the weight of FIG. 46, and then the macro division ratio (mdr)
And

C2000 cartridge: 100 × 0.4
+ 70 × 0.3 + 50 × 0.2 + 20 × 0.1 = 73 C4000 Cartridge: 30 × 0.4 + 20 × 0.3
Since + 10 × 0.2 + 50 × 0.1 = 25, the macro division ratio (mdr) is 73:25.
It turns out that. As described above, by adopting the weight when creating the macro division ratio, it is possible to perform prediction that reflects recent data. The above calculation is performed by the CPU 10
Needless to say, it is realized by 1. S4008
Is a process performed when the consumable product sales record period is shorter than the predetermined period. In this case, Consumables Macro Master DB
Referring to (N), a consumable item similar to the consumable item to be predicted is searched, and the macro division ratio (mdr) corresponding to the similar consumable item is adopted.

In step S4010, the consumable product demand forecast result (z) is divided according to the macro division ratio.

At S4011, the macro demand forecast result (FC6) is written in the macro demand forecast result DB (DB (Q)).

In S4012, the macro demand forecast result (FC6) is changed to the consumable demand forecast result (after correction) (FC2).
As a consumables demand forecast result (after correction) (DB (B))
Write in.

The consumables demand forecast result (after correction) is the CPU
It is displayed on the output unit 103 under the control of 101. Specifically, the demand forecasts as shown in FIGS. 37D and 37E are displayed in the display format (graph format and / or table format) of FIG.

FIG. 41 shows the consumables macro synthesis module 3
It is a transition diagram of 803 DB.

FIG. 42 shows the consumables macro disassembly module 3
It is a transition diagram of DB of 805. In the example of FIG. 42,
The macro division ratio is 80:20.

(3) Creating a decomposition ratio due to the effect of foreign exchange In general, in transactions between countries with different currencies, when the same product is sold in both countries, the product is transferred from a country with a weak currency to a country with a strong currency. It tends to be sold more. The reason will be described in the following example.

It is assumed that a certain product AA is sold for $ 100 in the US $ area and 100 euro in the Euro area when the exchange rate is EURO / US $ = 1.0. After that, it is assumed that the exchange rate becomes Euro / US $ = 1.1. At this time, if the seller in the Euro area sells the product AA for $ 100 to the US $ area, 110 Euro can be received without considering the export cost. Even if export costs such as transportation costs and tariffs are taken into consideration, if the exchange rate fluctuates significantly, it may be possible for the seller to make more profits, so the euro area seller will sell in the US $ area. Alternatively, the amount of sales to consumers may increase. When the exchange rate moves in the opposite direction, it is assumed that products are often sold from the US $ area to the EURO area. Even in the case of consumables, such a situation may occur when the exchange rate fluctuates greatly. For that reason, when selling products from different countries to countries with different exchange rates, when the accurate forecast cannot be calculated because the effect of exchange rate is not taken into account in the decomposition ratio calculated from the ratio of past sales results to each country only. Therefore, it is necessary to forecast the demand with a decomposition ratio that takes into consideration the effect of exchange rates.

The following is an example of the formula for calculating the decomposition ratio in consideration of the influence of exchange rates.・ Disassembly ratio Exchange correction coefficient (ERC) YY (preset (stored)) ・ Exchange rate reference (SER) currency AA / currency BB = ZZ
(Preset (stored)) When the pre-correction disassembly ratio of consumables is currency AA area: currency BB area = mdr1: mdr2, and the exchange rate moves to currency AA / currency BB = ZZ1 (ZZ1 Is
The latest actual exchange rate automatically obtained from a financial institution such as a bank or the future forecast value is adopted.) As an example of the calculation of the modified decomposition ratio, currency XX region: currency XY region = mdr1 + (ZZ1-ZZ) × YY: mdr2- (ZZ1-ZZ) * YY (Equation 35) When the exchange rate is Euro / US $ = 1.0, the pre-correction decomposition ratio of the consumables is EURO area: US $ area = 1:
2. Assume that the decomposition ratio exchange rate correction coefficient (ERC) is 2. [Example 1] When the exchange rate fluctuates to Euro / US $ = 0.9 The decomposition ratio is Euro: US $ = 1 + (0.9-1) ×
2: 2- (0.9-1) * 2 = 0.8: 2.2 = 4: 1
It becomes 1. [Example 2] When the exchange rate fluctuates to Euro / US $ = 1.1 The decomposition ratio is Euro: US $ = 1 + (1.1-1) ×
2: 2- (1.1-1) × 2 = 1.2: 1.8 = 2: 3
Becomes

FIG. 43 is a diagram showing a list of databases relating to the consumables macro demand forecast.

As is clear from FIGS. 37 to 43, according to the present invention, a more accurate prediction is performed as a whole by predicting by adding together the mutual influences on the markets and the sales of products that influence each other. Is possible. In addition, production, sales, and inventory planning can be performed based on highly accurate forecasts. As a result, it is possible to hold an appropriate inventory without missing a sales opportunity.

[0349]

As described above, according to the present invention, it is possible to support the planning of a consumables business based on the demand forecast result of the consumables.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of an information processing device for realizing a demand forecasting device, a method, and a program of the present invention.

FIG. 2 is a diagram showing a table for explaining prediction processing units according to the present embodiment.

FIG. 3 is a diagram showing an example of calculating a main unit sales record planned number x (t) from main unit sales record number a (t) and main unit sales plan number b (t) from January 2001 to December 2001. is there.

FIG. 4 is a diagram showing an example of the main unit operation record number y (t) from January 2001 to December 2001.

FIG. 5 is a diagram showing a residual rate function at installation A, installation B, and installation C.

FIG. 6 is a diagram showing a relationship between the number of installed main bodies and the number of operating main bodies.

FIG. 7 is a diagram showing correspondence between bases and consumable model.

FIG. 8 is a diagram showing a processing flow when predicting the number of operating main bodies.

FIG. 9 is a diagram showing a processing flow when predicting the average PV of the main body.

FIG. 10 is a diagram showing a processing flow when predicting the total PV of the main body.

FIG. 11 is a diagram showing a processing flow when predicting the demand for consumables.

FIG. 12 is a diagram showing a main body operating number prediction block, an average PV prediction block, and a total prediction PV block.

FIG. 13 is a diagram showing a consumables prediction block.

FIG. 14 shows an example of an installed diffusion coefficient j (t).

FIG. 15 is a diagram showing the number of installed units and the cumulative number of installed units for each month in the present embodiment.

FIG. 16 is an example showing changes in the residual rate function when the average life μ and the variation coefficient φ are changed.

FIG. 17 shows a module configuration of a program of the present invention.

FIG. 18 is a conceptual diagram of demand forecast for consumables.

FIG. 19 is a conceptual diagram of initial demand forecast.

FIG. 20 is a conceptual diagram of another-company reflected demand forecast.

[Fig. 21] Demand forecast (trend forecast) at the end of the sales period
It is a conceptual diagram of.

FIG. 22 is a diagram showing a consumables initial demand forecast, a consumables company reflected demand forecast, a consumables demand forecasting prediction method, and conditions for switching the forecasting method.

23 is a diagram showing a module configuration added to the module configuration of the program of FIG.

FIG. 24 is an overall flowchart.

FIG. 25 is a flowchart showing details of a consumable product initial demand prediction process.

FIG. 26 is a flowchart showing details of a consumables company reflected demand forecasting process.

FIG. 27 is a flowchart showing details of consumable goods trend demand prediction processing.

FIG. 28 is a diagram showing a flow of determining a prediction method.

FIG. 29 is a diagram showing a flow of determining a prediction method.

[Fig. 30] Fig. 30 is a diagram showing the transition of the database at the time of predicting the initial demand of consumables.

[Fig. 31] Fig. 31 is a diagram showing the transition of the database at the time of forecasting the demand reflected by the consumables company.

[Fig. 32] Fig. 32 is a diagram showing the transition of the database at the time of the consumable goods trend demand prediction.

FIG. 33 is a diagram showing a transition at the time of determining a prediction method.

FIG. 34 is a diagram showing various databases of the present invention.

FIG. 35 is a diagram showing various databases of the present invention.

FIG. 36 is a diagram showing an example of a consumable product sales record (RC) and a consumable product other-company reflection prediction target period (T (FC5)).

FIG. 37 is a diagram showing a conceptual diagram of consumables macro demand forecast.

FIG. 38 shows the configuration of a module for macro demand forecasting.

[Fig. 39] Fig. 39 is a schematic diagram of a consumables macro demand forecast flow.

FIG. 40 is a detailed diagram of a consumables macro demand forecast flow.

FIG. 41 is a database of a consumables macro synthesis module 3803.
FIG.

FIG. 42 is a DB of a consumables macro disassembly module 3805.
FIG.

FIG. 43 is a diagram showing a list of databases relating to consumables macro demand forecast.

FIG. 44 is a diagram showing a screen when the demand forecast result of a consumable item is displayed on the output unit 103.

FIG. 45 is a diagram showing a table showing the sales record of consumables until October of a certain year.

FIG. 46 is a diagram showing a graph showing weights to be added to sales records.

[Explanation of symbols]

101 CPU 102 Input section 103 output section 104 external storage device 105 ROM 106 RAM 107 network interface 108 internal storage device 109 bus

Claims (10)

[Claims] 1. A consumables demand forecasting program having an instruction to a computer for predicting a demand for a consumables consumed when an output device for outputting an output outputs the output, which is output by the product. An output quantity input control function for controlling an output quantity input means for inputting an output quantity of a product, a sales quantity input control function for controlling a sales quantity input means for inputting a sales quantity of consumables, the output quantity, and the sales A computer to realize a storage control function of controlling the storage of the amount in the memory, and a prediction function of predicting a consumption amount of a consumable product for outputting a future output product from the output amount and the sales amount. A characteristic consumables demand forecasting program. 2. A consumables demand forecasting program having a command to a computer for predicting a demand for a consumables consumed when an output device for outputting an output produces the output, the product for each unit time. Output amount input control function for controlling the output amount input means for inputting the output amount of the output product, and the sales amount input function for controlling the sale amount input means for inputting the sales amount of consumables per unit time, A storage control function for controlling storage of the output amount and the sales amount in a memory, and a prediction function for predicting a consumption amount of a consumable item for outputting a future output product from the output amount and the sales amount, A consumables demand forecasting program for causing a computer to realize a storage function of storing the consumption of consumables predicted by the forecasting function in a memory. 3. The consumable goods sold in each unit time are consumed according to a predetermined function, and the output amount of the output product for each unit time is the unit time of the consumable goods sold until then. The product of adding a predetermined coefficient to the sum of the consumption amount in, further has a calculation function of calculating the predetermined function and the predetermined coefficient from the output amount and the sales amount, the prediction function, The consumable product according to claim 2, wherein the future consumption amount of the consumable product is predicted by assuming that a product to be sold in each unit time in the future is consumed according to the predetermined function and the predetermined coefficient. Demand forecasting program. 4. The consumable goods sold in each unit time are consumed according to a predetermined function, and the output amount of the output product for each unit time is the unit time of the consumable goods sold until then. The sum of the consumption amount in the product is multiplied by a predetermined coefficient, further having a function coefficient input function for controlling the input of the predetermined function and the predetermined coefficient, the prediction function, in the future each The consumable goods demand forecasting program according to claim 2, wherein the consumption quantity of the consumable goods in the future is predicted assuming that the product sold per unit time is consumed according to the predetermined function and the predetermined coefficient. . 5. A comparison function for counting the number of unit times in which the output amount is present and comparing the number with a predetermined threshold value, and when the number is equal to or more than the threshold value by the comparison function, The prediction function predicts future consumption of consumables, assuming that a product to be sold in each unit time in the future is consumed according to the predetermined function and the predetermined coefficient. 4. The consumables demand forecast program described in 4. 6. If the number is less than the threshold value by the comparison function, the prediction function assumes that products to be sold in each unit time in the future are consumed according to the predetermined function and the predetermined coefficient. The consumables demand forecasting program according to claim 3 or 4, which predicts future consumption of consumables. 7. The consumable goods demand forecast program according to claim 2, wherein the unit time is any one of an annual unit, a monthly unit, a week unit, and a daily unit. 8. The consumable product according to claim 1, wherein the predicting unit predicts the consumable product consumption amount including a change in the consumable product consumption amount depending on the season. Demand forecasting program. 9. An apparatus for predicting the number of operating products, which implements the function of the program for predicting the number of operating products, according to any one of claims 1 to 8. 10. A consumables demand forecasting method for forecasting a demand for a consumables consumed when an output device for outputting an output produces the output, the output amount of the output produced by the product, and An input step of inputting the sales amount of the consumable item, a storage step of storing the output amount and the sales amount in a memory, and a consumption amount of the consumable item for outputting a future output product from the output amount and the sales amount And a forecasting step for forecasting the demand.